L. Ahorner and W. Rosenhauer. Probability distribution of earthquake accelerations for the sites in Western
Germany. In Proceedings of Fifth European Conference on Earthquake Engineering, 1975. Not seen. Reported
in Makropoulos and Burton (1985).

S. Akkar and J. J. Bommer. Empirical equations for the prediction of PGA, PGV and spectral accelerations
in Europe, the Mediterranean region and the Middle East. Seismological Research Letters, 81(2):195–206,
Mar/Apr 2010.

S. Akkar and Z. Çağnan. A local ground-motion predictive model for Turkey and its comparison with other
regional and global ground-motion models. Bulletin of the Seismological Society of America, 100(6):2978–2995,
Dec 2010.

N. Ambraseys. Ground motions in the near field of small-magnitude earthquakes. In Proceedings ofthe Commission on the Safety of Nuclear Installations, Organisation of Economic Cooperation in Europe,
volume 1, pages 113–136, Paris, 1975a. Not seen. Reported in Ambraseys (1978a).

J. G. Anderson and S. E. Hough. A model for the shape of the Fourier amplitude spectrum of acceleration
at high frequencies. Bulletin of the Seismological Society of America, 74(5):1969–1993, Oct 1984.

J. G. Anderson and Y. Lei. Nonparametric description of peak acceleration as a function of magnitude,
distance, and site in Guerrero, Mexico. Bulletin of the Seismological Society of America, 84(4):1003–1017,
1994.

M. A. Ansary. Engineering characteristics of ground motions recorded by northeast Indian strong motion
instrumentation network from 2005 to 2013. In Proceedings of the Tenth U.S. National Conference onEarthquake Engineering, Jul 2014.

Ö. Aydan. Inference of seismic characteristics of possible earthquakes and liquefaction and landslide risks
from active faults. In The 6th National Conference on Earthquake Engineering of Turkey, volume 1, pages
563–574, 2007. Not seen. In Turkish.

C.-E. Baag, S.-J. Chang, N.-D. Jo, and J.-S. Shin. Evaluation of seismic hazard in the southern part of
Korea. In Proceedings of the Second International Symposium on Seismic Hazards and Ground Motion in theRegion of Moderate Seismicity, 1998. Not seen. Reported in Nakajima et al. (2007).

W. H. Bakun. MMI attenuation and historical earthquakes in the basin and range province of western
North America. Bulletin of the Seismological Society of America, 96(6):2206–2220, Dec 2006b. doi:
10.1785/0120060045.

T. Beyaz. Development of a new attenuation relationship of seismic energy for Turkey using the strongmotion records free of soil effect. PhD thesis, Ankara University, Turkey, 2004. Not seen. Reported in Selcuk
et al. (2010).

K. Beyer and J. J. Bommer. Relationships between median values and between aleatory variabilities for
different definitions of the horizontal component of motion. Bulletin of the Seismological Society of America,
96(4A):1512–1522, Aug 2006. doi: 10.1785/0120050210.

K. W. Campbell. The dependence of peak horizontal acceleration on magnitude, distance, and site effects for
small-magnitude earthquakes in California and eastern North America. Bulletin of the Seismological Societyof America, 79(5):1311–1346, Oct 1989.

K. W. Campbell. Empirical prediction of near-source ground motion from large earthquakes. In Proceedingsof the International Workshop on Earthquake Hazard and Large Dams in the Himalaya. Indian National Trust
for Art and Cultural Heritage, New Delhi, India, Jan 1993.

K. W. Campbell. Prediction of strong ground motion using the hybrid empirical method and its use in the
development of ground-motion (attenuation) relations in eastern North America. Bulletin of the SeismologicalSociety of America, 93(3):1012–1033, 2003b.

K. W. Campbell and Y. Bozorgnia. Near-source attenuation of peak horizontal acceleration from worldwide
accelerograms recorded from 1957 to 1993. In Proceedings of the Fifth U.S. National Conference on EarthquakeEngineering, volume III, pages 283–292, Jul 1994.

K. W. Campbell and Y. Bozorgnia. Next Generation Attenuation (NGA) empirical ground motion models:
Can they be used in Europe? In Proceedings of First European Conference on Earthquake Engineering andSeismology (a joint event of the 13thECEE& 30th General Assembly of theESC), Sep 2006b. Paper no. 458.

Y. Chen and Y.-X. Yu. The development of attenuation relations in the rock sites for periods (T = 0.04 ~10s, ξ = 0.05) based on NGA database. In Proceedings of Fourteenth World Conference on EarthquakeEngineering, 2008a. Paper no. 03-02-0017.

W. J. Cousins, J. X. Zhao, and N. D. Perrin. A model for the attenuation of peak ground acceleration in
New Zealand earthquakes based on seismograph and accelerograph data. Bulletin of the New Zealand Societyfor Earthquake Engineering, 32(4):193–220, Dec 1999.

L. Danciu. Development of a system to assess the earthquake damage potential for buildings: Intensiometer.
PhD thesis, Laboratory of Seismology, Department of Geology, University of Patras, Greece, 2006.

J. Douglas. Preface of special issue: A new generation of ground-motion models for europe and the middle
east. Bulletin of Earthquake Engineering, 12(1):307–310, 2014. doi: 10.1007/s10518-_013-_9535-_3.

J. Douglas and H. Halldórsson. On the use of aftershocks when deriving ground-motion prediction equations.
In Proceedings of the Ninth U.S. National and 10th Canadian Conference on Earthquake Engineering: ReachingBeyond Borders, 2010. Paper no. 220.

D. J. Dowrick and S. Sritharan. Attenuation of peak ground accelerations in some recent New Zealand
earthquakes. Bulletin of the New Zealand National Society for Earthquake Engineering, 26(1):3–13, 1993. Not
seen. Reported in Stafford (2006).

B. Edwards and D. Fäh. Measurements of stress parameter and site attenuation from recordings of moderate
to large earthquakes in Europe and the Middle East. Geophysical Journal International, 194(2):1190–1202,
Aug 2013a. doi: 10.1093/gji/ggt158.

B. Edwards and A. Rietbrock. A comparative study on attenuation and source-scaling relations in the
Kanto, Tokai, and Chubu regions of Japan, using data from Hi-Net and KiK-Net. Bulletin of the SeismologicalSociety of America, 99(4):2435–2460, Aug 2009. doi: 10.1785/0120080292.

L. Esteva. Geology and probability in the assessment of seismic risk. In Proceedings of the 2ndInternational Conference of the Association of Engineering Geology, Sao Paulo, 1974. Not seen. Reported in
Ambraseys (1978a).

E. Faccioli and D. Agalbato. Attenuation of strong-motion parameters in the 1976 Friuli, Italy, earthquakes.
In Proceedings of the Second U.S. National Conference on Earthquake Engineering, pages 233–242, 1979.

E. Faccioli and C. Cauzzi. Macroseismic intensities for seismic scenarios, estimated from instrumentally
based correlations. In Proceedings of First European Conference on Earthquake Engineering and Seismology(a joint event of the 13thECEE& 30th General Assembly of theESC), 2006. Paper number 569.

E. Faccioli, A. Bianchini, and M. Villani. New ground motion prediction equations for T > 1s and their
influence on seismic hazard assessment. In Proceedings of the University of Tokyo Symposium on Long-PeriodGround Motion and Urban Disaster Mitigation, Mar 2010.

E. H. Field. A modified ground-motion attenuation relationship for southern California that accounts for
detailed site classification and a basin-depth effect. Bulletin of the Seismological Society of America, 90(6B):
S209–S221, Dec 2000.

R. Foulser-Piggott and K. Goda. New prediction equations of Arias intensity and cumulative absolute
velocity for Japanese earthquakes. In Proceedings of Second European Conference on Earthquake Engineeringand Seismology (a joint event of the 14thECEE& 31st General Assembly of theESC), Aug 2014. Paper no.
918.

C. Gómez-Soberón, A. Tena-Colunga, and M. Ordaz. Updated attenuation laws in displacement and
acceleration for the Mexican Pacific coast as the first step to improve current design spectra for base-isolated
structures in Mexico. In Proceedings of the Eighth U.S. National Conference on Earthquake Engineering, Apr
2006. Paper no. 1010.

B. Hernandez and F. Cotton. Empirical determination of the ground shaking duration due to an earthquake
using strong motion accelerograms for engineering applications. In Proceedings of Twelfth World Conferenceon Earthquake Engineering, 2000. Paper no. 2254/4/A.

B. Hernandez, Y. Fukushima, R. Bossu, and J. Albaric. Seismic attenuation relation for Hualien (Taiwan)
at the free surface and down to 52.6m deep. In Proceedings of Third International Symposium on the Effectsof Surface Geology on Seismic Motion, volume 1, pages 145–154, 2006. Paper number 008.

N. Humbert and E. Viallet. An evaluation of epistemic and random uncertainties included in attenuation
relationship parameters. In Proceedings of Fourteenth World Conference on Earthquake Engineering, 2008.
Paper no. 07-0117.

H. Hwang. Attenuation of Arias intensity based on data from the Chi-Chi earthquake. In Proceedings ofthe Eighth U.S. National Conference on Earthquake Engineering, 2006. Paper No. 306. Not seen. Cited in
Alarcón (2007).

M. Kamiyama. Effects of subsoil conditions and other factors on the duration of earthquake ground shakings.
In Proceedings of Eighth World Conference on Earthquake Engineering, volume II, pages 793–800, 1984.

M. Kamiyama. Regression analyses of strong-motion spectra in terms of a simplified faulting source model.
In Proceedings of the Fourth International Conference on Soil Dynamics and Earthquake Engineering, pages
113–126, Oct 1989.

M. Kamiyama. An attenuation model for the peak values of strong ground motions with emphasis on local
soil effects. In Proceedings of the First International Conference on Earthquake Geotechnical Engineering,
volume 1, pages 579–585, 1995.

M. Leonard. Consistent MMI area estimation for Australian earthquakes. In Proceedings of the Tenth PacificConference on Earthquake Engineering: Building an Earthquake-Resilient Pacific, Nov 2015. Paper number
170.

A. Mahdavian. Empirical evaluation of attenuation relations of peak ground acceleration in the Zagros and
central Iran. In Proceedings of First European Conference on Earthquake Engineering and Seismology (a jointevent of the 13thECEE& 30th General Assembly of theESC), 2006. Paper number 558.

M. R. Mahdavifar, M. K. Jafari, and M. R. Zolfaghari. The attenuation of Arias intensity in Alborz and
central Iran. In Proceedings of the Fifth International Conference on Seismology and Earthquake Engineering,Tehran, Iran, 2007. Not seen. Cited in Chousianitis et al. (2014).

K. C. Makropoulos. The statistics of large earthquake magnitude and an evaluation of Greek seismicity.
PhD thesis, University of Edinburgh, UK, 1978. Not seen.

M. I. Manic. A new site dependent attenuation model for prediction of peak horizontal acceleration in
Northwestern Balkan. In Proceedings of Eleventh European Conference on Earthquake Engineering, 1998.

T. Matuschka. Assessment of seismic hazards in New Zealand. Technical Report 222, Department of Civil
Engineering, School of Engineering, University of Auckland, 1980. Not seen. Reported in Stafford (2006).

T. Matuschka and B. K. Davis. Derivation of an attenuation model in terms of spectral acceleration for
New Zealand. In Pacific Conference on Earthquake Engineering, 1991. Not seen. Reported in Stafford (2006).

R. K. McGuire and T. P. Barnhard. The usefulness of ground motion duration in prediction of severity of
seismic shaking. In Proceedings of the Second U.S. National Conference on Earthquake Engineering, pages
713–722, 1979.

B. Mohammadioun. The prediction of response spectra for the anti-seismic design of structures specificity
of data from intracontinential environments. European Earthquake Engineering, V(2):8–17, 1991.

B. Mohammadioun. Prediction of seismic motion at the bedrock from the strong-motion data currently
available. In Proceedings of Tenth European Conference on Earthquake Engineering, volume 1, pages 241–245,
1994a.

T. Nishimura and M. Horike. The attenuation relationships of peak ground accelerations for the horizontal
and the vertical components inferred from Kyoshin network data. Journal of Structural and ConstructionEngineering (Transactions ofAIJ), 571:63Ű–70, 2003. In Japanese. Not seen. Cited in Edwards and
Rietbrock (2009).

D. Olszewska. Attenuation relations of ground motion acceleration response spectra for the Polkowice region.
Publications of the Institute of Geophysics of the Polish Academy of Sciences, M-29(395), 2006.

A. Pancha and J. J. Taber. Attenuation of weak ground motions: A report prepared for the New Zealand
Earthquake Commission. Technical report, School of Earth Sciences, Victoria University of Wellington, New
Zealand, 1997. Not seen. Reported in Stafford (2006).

F. Scherbaum, F. Cotton, and P. Smit. On the use of response spectral-reference data for the selection and
ranking of ground-motion models for seismic-hazard analysis in regions of moderate seismicity: The case of rock
motion. Bulletin of the Seismological Society of America, 94(6):2164–2185, Dec 2004. doi: 10.1785/0120030147.

M. Sharma and H. Bungum. New strong ground-motion spectral acceleration relations for the Himalayan
region. In Proceedings of First European Conference on Earthquake Engineering and Seismology (a joint eventof the 13thECEE& 30th General Assembly of theESC), 2006. Paper number 1459.

S. Shi and J. Shen. A study on attenuation relations of strong earth movements in Shanghai and its adjacent
area. Earthquake Research in China, 19:315–323, 2003. In Chinese. Not seen. Cited in Cole et al. (2008).

H. Si and S. Midorikawa. New attenuation relationships for peak ground acceleration and velocity
considering effects of fault type and site condition. Journal of Structural and Construction Engineering, AIJ,
523:63–70, 1999. In Japanese with English abstract. Not seen.

H. Si and S. Midorikawa. New attenuation relations for peak ground acceleration and velocity considering
effects of fault type and site condition. In Proceedings of Twelfth World Conference on Earthquake Engineering,
2000. Paper No. 0532.

P. Stafford, J. Berrill, and J. Pettinga. New empirical predictive equations for the Fourier amplitude
spectrum of acceleration and Arias intensity in New Zealand. In Proceedings of First European Conferenceon Earthquake Engineering and Seismology (a joint event of the 13thECEE& 30th General Assembly of theESC), 2006. Paper number 820.

F. Sun and K. Peng. Attenuation of strong ground motion in western U.S.A. Earthquake Research in China,
7(1):119–131, 1993.

C.-H. Sung and C.-T. Lee. A new methodology for quantification of the systematic path effects on
ground-motion variability. Bulletin of the Seismological Society of America, 106(6):2796–2810, Dec 2016. doi:
10.1785/0120160038.

K. Tamura, Y. Sasaki, and K. Aizawa. Attenuation characteristics of ground motions in the period range
of 2 to 20 seconds — for application to the seismic design of long-period structures. In Proceedings of theFourth U.S. National Conference on Earthquake Engineering, volume 1, pages 495–504, May 1990.

H. Tong and T. Katayama. Peak acceleration attenuation by eliminating the ill-effect of the correlation
between magnitude and epicentral distance. In Proceedings of Ninth World Conference on EarthquakeEngineering, volume II, pages 349–354, 1988.

G. R. Toro and W. J. Silva. Scenario earthquakes for Saint Louis, MO, and Memphis, TN, and seismic
hazard maps for the central United States region including the effect of site conditions. Technical report, Jan
2001. Research supported by the U.S. Geological Survey (USGS), under award number 1434-HQ-97-GR-02981.

M. D. Trifunac and A. G. Brady. On the correlation of peak acceleration of strong motion with earthquake
magnitude, epicentral distance and site conditions. In Proceedings of the U.S. National Conference onEarthquake Engineering, pages 43–52, 1975a.

Y. B. Tsai, F. W. Brady, and L. S. Cluff. An integrated approach for characterization of ground motions in
PG&E’s long term seismic program for Diablo Canyon. In Proceedings of the Fourth U.S. National Conferenceon Earthquake Engineering, volume 1, pages 597–606, May 1990.

B.-Q. Wang, F. T. Wu, and Y.-J. Bian. Attenuation characteristics of peak acceleration in north China and
comparison with those in the eastern part of North America. Acta Seismologica Sinica, 12(1):26–34, 1999.
doi: 10.1007/s11589-_999-_0004-_7.

G. Wang and X. Tao. A new two-stage procedure for fitting attenuation relationship of strong ground
motion. In Proceedings of the Sixth International Conference on Seismic Zonation, Nov 2000.

K. Yamabe and K. Kanai. An empirical formula on the attenuation of the maximum acceleration of
earthquake motions. In Proceedings of Ninth World Conference on Earthquake Engineering, volume II, pages
337–342, 1988.

K.-H. Yun and D.-H. Park. Development of site-specific ground-motion attenuation relations in Korea Ů–
examples for the nuclear power plant sites. In The 5th International Workshop on the Fundamental Researchfor Mitigating Earthquake Hazards, 2005. Not seen. Cited in Choi et al. (2009).

H. Zafarani and M. Soghrat. Simulation of ground motion in the Zagros region of Iran using the specific
barrier model and the stochastic method. Bulletin of the Seismological Society of America, 102(5):2031–2045,
Oct 2012. doi: 10.1785/0120110315.

M. Zare and S. Sabzali. Spectral attenuation of strong motions in Iran. In Proceedings of Third InternationalSymposium on the Effects of Surface Geology on Seismic Motion, volume 1, pages 749–758, 2006. Paper
number 146.

M. Zaré, M. Ghafory-Ashtiany, and P.-Y. Bard. Attenuation law for the strong-motions in Iran. In
Proceedings of the Third International Conference on Seismology and Earthquake Engineering, Tehran,
volume 1, pages 345–354, 1999.